Aflatoxins – product contamination and preventive measures

7th International Scientific Conference Modern Trends in Agricultural Production, Rural Development and Environmental Protection (2025) [pp. 263-269]  

AUTHOR(S) / АУТОР(И): Ivana Bošković , Dragutin Đukić , Leka Mandić ,  Monika Stojanova ,  Marina T. Stojanova ,  Zoranka Malešević , Vesna Đurović , Marijana Pešaković 

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DOI: 10.46793/7thMTAgricult.25B

ABSTRACT / САЖЕТАК:

In today’s ecologically compromised living conditions, the issue of microbial contamination of food by pathogenic microorganisms and their toxins throughout the entire food chain (from farm to fork) is gaining increasing global importance. This is primarily aimed at protecting the health of humans and animals, safeguarding the economy and trade, and ensuring strict compliance with legal regulations. Over the past decade, the greatest attention has been focused on examining the concentration of aflatoxins in food of both plant and animal origin. The permitted concentration of aflatoxins in food products ranges between 4–30 µg/kg. However, the European Union has established the strictest standard, with AFB1 and total aflatoxins not exceeding 2 µg/kg and 4 µg/kg, respectively, in many products intended for direct human consumption. Through the application of physical, chemical, and biological preventive measures, as well as practices related to cultivation, harvesting, and storage of animal feed and cereals, and measures applied during production, transport, and storage processes, food contamination by mycotoxins can be significantly reduced.

KEYWORDS / КЉУЧНЕ РЕЧИ:

aflatoxins, food contamination, preventive measures

ACKNOWLEDGEMENT / ПРОЈЕКАТ:

REFERENCES / ЛИТЕРАТУРА:

  • Chouvenc, T., Su, N.Y., & Grace, J.K. (2011). Fifty years of attempted biological control of termites – Analysis of a failure. Biological Control, 59(2), 69–82.
  • (2007). European Commission. Commission Regulation (EC) No 1126/2007 of 28 September 2007 amending regulation (EC) No 1881/2006 setting maximum levels for certain contaminants in foodstuffs as regards Fusarium toxins in maize and maize products. Official Journal of the European Union, L255, 14–17.
  • (2010). European Commission. Commission Regulation (EC) No 165/2010 of 26 February 2010 amending Regulation (EC) No 1881/2006 setting maximum levels for certain contaminants in foodstuffs as regards aflatoxins. Official Journal of the European Union, L50, 8–12.
  • European Food Safety Authority. (2013). Aflatoxins (sum of B1, B2, G1, G2) in cereals and cereal-derived food products. EFSA Supporting Publications, 10, EN-406.
  • Food and Agriculture Organization of the United Nations. (1993). Sampling plans for aflatoxin analysis in peanuts and corn: Report of an FAO Technical Consultation, Rome, 3–6 May 1993. FAO Food and Nutrition Paper No. 55. Rome: Food and Agriculture Organization of the United Nations.
  • Gowda, N.K.S., Malathi, V., & Suganthi, R.U. (2004). Effect of some chemical and herbal compounds on growth of Aspergillus parasiticus and aflatoxin production. Animal Feed Science and Technology, 116(3–4), 281–291.
  • Singapore Food Agency. (n.d.). Aflatoxins and food safety. Retrieved March 6, 2025, from https://www.sfa.gov.sg/food-safety-tips/food-risk-concerns/risk-at-a-glance/aflatoxins-and-food-safety
  • Bioimagen. (n.d.). Aspergillus parasiticus. Retrieved March 6, 2025, from https://Bioimagen: Aspergillus parasiticus. Autor: PIMCD2012 Proyecto Microbiología
  • International Agency for Research on Cancer. (1993). Some naturally occurring substances: Food items and constituents, heterocyclic aromatic amines and mycotoxins. IARC Monographs on the Evaluation of Carcinogenic Risks to Humans, 56, 245–395. Lyon, France: World Health Organization.
  • Kabak, B. (2021). Aflatoxins in foodstuffs: Occurrence and risk assessment in Turkey. Journal of Food Composition and Analysis, 96, Article 103734.
  • Kamle, M., Mahato, D.K., Devi, S., Lee, K.E., Kang, S.G., & Kumar, P. (2019). Fumonisins: Impact on agriculture, food, and human health and their management strategies. Toxins, 11(6), Article 328.
  • Magan, N. (2007). Fungi in extreme environments. Mycota, 4, 85–103.
  • Nesci, A., Etcheverry, M., & Magan, N. (2004). Osmotic and matric potential effects on growth, sugar alcohol and sugar accumulation by Aspergillus section Flavi strains from Argentina. Journal of Applied Microbiology, 96(5), 965–972.
  • Pérez-Fernández, B., & de la Escosura-Muñiz, A. (2022). Electrochemical biosensors based on nanomaterials for aflatoxins detection: A review (2015–2021). Analytica Chimica Acta, 1212, 339658.
  • Santin, E. (2005). Mould growth and mycotoxin production. In Mycotoxin blue book (pp. 225–234). Nottingham: University Press, United Kingdom.
  • Šarkanj, B., Kipčić, D., Vasič Rački, D., Delaš, F., Galić, K., Katalenić, M., Dimitrov, N., & Klapec, T. (2010). Hemijske i fizikalne opasnosti u hrani. Osijek: Hrvatska agencija za hranu.
  • World Health Organization. (2022). Mycotoxins. Retrieved June 6, 2025, from https://www.who.int/news-room/fact-sheets/detail/mycotoxins
  • Wu, F., & Guclu, H. (2012). Aflatoxin regulations in a network of global maize trade. PLOS ONE, 7(9), e45151.
  • Zhang, K., & Banerjee, K. (2020). A review: Sample preparation and chromatographic technologies for detection of aflatoxins in foods. Toxins, 12(9), 539.